DE102013009642A1 - Measuring system, reaction carrier, measuring method and optical flow sensor - Google Patents

Abstract

The invention relates to a reaction carrier (14) for a measuring system (10) for measuring a concentration of gas and / or aerosol components of a gas mixture and to such a measuring system (10) and corresponding measuring method. The reaction carrier (14) comprises at least one flow channel (42), wherein the flow channel (42) forms a reaction chamber (46) with a reactant (48), which is adapted to at least one component to be measured of the gas mixture or a reaction product measuring component to enter into an optically detectable reaction. The flow channel (42) is at least partially filled with particles (100, 102, 104, 110) having a starting position before the gas mixture flows through the flow channel (42), and which by a gas flow through the flow channel (42) in a Flow position can be applied, wherein the particles (100, 102, 104, 110) are formed so that the particles (100, 102, 104, 110) in the starting position and the particles (100, 102, 104, 110) in the flow position can be visually distinguished. The invention further relates to an optical flow sensor (109) for determining a flow of a fluid.

Description

The present invention relates to a measuring system for measuring a concentration of gas and / or an aerosol-shaped components of a gas mixture and a reaction support for such a measuring system with at least one flow channel, wherein the flow channel forms a reaction chamber with a reactant, which is designed to with at least one component to be measured of the gas mixture or a reaction product of the component to be measured to enter into an optically detectable reaction. The invention further relates to a measuring method for measuring a concentration of gas and / or aerosol-shaped components of a gas mixture and an optical flow sensor.

Gas test tubes are known from the prior art, which are filled with a reactant which undergoes an optically recognizable reaction with a particular chemical compound. In this case, for example, with a hand pump, a defined amount of a gas mixture is pumped through the gas test tube. Subsequently, a concentration of the chemical compound to be measured is determined by means of a discoloration of the reaction substance.

In addition, so-called chip-based measuring systems are known in which the reactant is provided in a plurality of reaction chambers arranged on a reaction chamber, which can be used in each case for a measurement. The reaction carrier can be introduced into a measuring device which recognizes the reaction carrier and carries out a corresponding measuring method for measuring a concentration of the corresponding component of the gas mixture. For measurements in which no concentration is measured because the component to be measured is not present or below a detection threshold in the gas mixture, a functional test of the measuring system is required to rule out a malfunction.

The aim of the invention is to provide a simple sensor system for such a measuring system and a corresponding measuring method.

The object of the invention is achieved by a reaction carrier for a measuring system for measuring a concentration of gas- and / or aerosol-shaped components of a gas mixture, with at least one flow channel, wherein the flow channel forms a reaction chamber with a reaction substance which is designed to be at least one to be measured component of the gas mixture or a reaction product of the component to be measured to enter into an optically detectable reaction. The flow channel is at least partially filled with particles having a starting position before the gas mixture flows through the flow channel, and are acted upon by a gas flow through the flow channel in a flow position, wherein the particles are formed so that the particles in the starting position and the Particles in the flow position can be optically distinguished. In this way, a flow of the gas mixture through the flow channel can be determined optically, whereby the sensor system of a measuring system belonging to the measuring device can be simplified by, for example, the optically detectable reaction and the flow of the gas mixture is detected and determined via a common optical sensor. Thus, no separate sensor is needed to determine a mass flow.

It is possible that the particles have different sizes, wherein in the starting position particles of different sizes are mixed and in the flow position, the particles of different sizes are at least partially segregated. The gas stream leaches small particles and deposits in low flow areas and larger particles align with the flow. As a result of this separation, the intensity distribution of the image of the flow channel is changed and the contrast is increased.

The particles may also have a flow shape to align in a flow of gas in a predetermined orientation in the flow direction in its flow position. In this way, the particles can be oriented in a certain direction and, in particular, an isotropic or chaotic starting position can be distinguished from an aligned flow position. For example, the particles are drop-shaped.

It is also possible that the particles are colored in order to facilitate and enhance optical discrimination of the positions of the particles.

Furthermore, the particles may have mechanical, electrical and / or magnetic properties in order to be moved into a reset position by a mechanical, electrical and / or magnetic restoring force acting on the particles, wherein the particles are configured such that the particles are in the reset position and the particles in the flow position can be visually distinguished. In this way, on the one hand, a measurement can be repeated or a continuous measurement can be carried out, since they are acted upon by the restoring force in each case in their reset position and thus in reducing the Gas stream are moved to their reset position. On the other hand, a first ordered distribution of the particles in their return positions can be set against a second ordered distribution of the particles in their flow positions, whereby a determination of the positions of the particles can be simplified.

The invention further relates to a measuring system for measuring a concentration of gas and / or aerosol components of a gas mixture with a reaction carrier according to one of the preceding claims and a measuring device having an optical sensor, which detects the flow channel of the reaction carrier and is designed to the Optically determine the starting position and flow position of the particles. In this way, a flow of the gas mixture through the flow channel can be determined optically, whereby the sensor system of a measuring system belonging to the measuring device can be simplified by, for example, the optically detectable reaction and the flow of the gas mixture is detected and determined via a common optical sensor. Thus, no separate sensor is needed to determine a mass flow.

Furthermore, the measuring device and / or the reaction carrier can be designed to generate an electric or magnetic field in the flow channel of the reaction carrier. In this way, an electrical or magnetic restoring force for corresponding particles can be generated.

Preferably, the restoring force can be dynamically modulated. In this way, the accuracy of the measurement can be improved.

The invention further relates to a measuring method for measuring a concentration of gas- and / or aerosol-shaped components of a gas mixture with a reaction carrier described above or a measuring system described above, comprising the steps of recording a reference image of the flow channel before a gas flow through the flow channel the particles are in their initial position, the recording of a flow pattern of the flow channel during a conveyance of a gas flow through the flow channel and the determination of the flowing gas flow through the flow channel by evaluation of the reference image and the flow pattern. By evaluating the reference image and the flow pattern, it is possible to determine a change in the position of the particles and thus a gas flow through the flow channel, thereby enabling an optical determination of a gas flow through the flow channel.

According to a variant of the method, the measuring method comprises the method step of generating a restoring force during the conveyance of the gas flow through the flow channel, which acts on the particles in a return position. This allows a repeated or continuous measurement.

Further, the measuring method may include the step of dynamically modulating the restoring force while conveying the gas flow through the flow channel such that the particles reciprocate between the reset position and the flow position. In this way, a continuous measurement with increased accuracy can be performed.

The invention further relates to an optical flow sensor for determining a flow of a fluid, with a transparent flow channel which is at least partially filled with particles. The particles have a flow form for directing to a flow position in a gas flow in a predetermined orientation in the flow direction and mechanical, electrical and / or magnetic properties to return to a reset position by a mechanical, electrical and / or magnetic restoring force acting on the particles to be acted upon, wherein the particles are formed so that the particles in the reset position and the particles can be optically distinguished in the flow position. Furthermore, a restoring device for generating the mechanical, electrical and / or magnetic restoring force, an optical sensor element which is designed to detect a change in position of the particles from the starting position to the flow position and a control unit is provided, which is designed to be detected by means of Change in position of the particles to determine the flow of the fluid. Such a flow sensor allows an optical determination of a flow through the flow channel.

The embodiments described above may be combined as desired with one another and with the aspects described above in order to achieve advantages according to the invention. Further features and advantages of the invention will become apparent from the embodiments described below, wherein:

1 shows a schematic view of a first embodiment of a measuring system according to the invention with a measuring device and a reaction carrier according to the invention;

2 a detailed view of the measuring system 1 shows;

3 a detailed view of the measuring system 1 with introduced reaction carrier shows;

4a shows a flow channel according to a first embodiment of a reaction carrier with particles in their starting position;

4b shows a flow channel according to the first embodiment of a reaction carrier with particles in its flow position;

5 shows a diagram of an intensity distribution of images of the flow channel according to the first embodiment;

6 shows a flow channel according to a second embodiment of a reaction carrier;

7a a portion of the flow channel according to 6 with particles in their starting position;

7b a portion of the flow channel according to 6 with particles in their flow position;

8a shows a portion of the flow channel of a reaction carrier according to a third embodiment with particles in their reset position;

8b shows a portion of the flow channel of a reaction carrier according to the third embodiment with particles in its flow position; and

9 shows a portion of the flow channel of a reaction carrier according to a fourth embodiment with particles in their return position.

1 shows a schematic view of a gas measuring system, hereinafter also measuring system 10 designated. The measuring system 10 includes a measuring device 12 and a reaction carrier 14 , The reaction carrier 14 has at least one flow channel 42 on which a reaction chamber 46 with a reactant 48 forms. The reactant 48 is designed to enter into an optically detectable reaction with at least one component to be measured of a gas mixture or a reaction product of the component to be measured. In this way, either the component to be measured can react directly with the reaction substance or an intermediate reaction can be provided in which the component to be measured reacts with an intermediate reaction substance and the resulting reaction product then undergoes the optically detectable reaction with the reaction substance ,

The measuring device 12 includes a gas delivery assembly 2 with a gas conveyor 28 for conveying the gas mixture through the flow channel 42 of the reaction carrier 14 ,

The gas delivery assembly 2 further comprises a gas inlet channel 16 with a gas mixture inlet 20 through which the gas mixture enters the gas inlet channel 16 can flow in, and a gas connection 22 , which with the flow channel 42 of the reaction carrier 14 can be connected.

Furthermore, the gas delivery assembly includes 2 a gas drainage channel 18 with a gas connection 24 , which with the flow channel 42 of the reaction carrier 14 can be connected. The gas conveyor 28 is in the gas drainage channel 18 arranged and allows a conveying of the gas mixture in a in 1 indicated by arrows flow direction.

A control unit 31 is provided, which is designed to control or regulate a flow of the gas mixture through the flow channel as a function of at least one reaction rate parameter. Reaction rate parameters can be, for example, the propagation velocity of a reaction front of the optically detectable reaction or a temperature of the flow through the channel 42 be flowing gas mixture. To measure the temperature of the flow channel 42 flowing gas mixture are temperature measuring elements 84 provided, which is a measurement of the temperature of the gas mixture directly in the flow channel 42 of the reaction carrier 14 , or indirectly via a measurement of the temperature of the reaction carrier 14 and / or the measuring device 12 ,

The measuring device 12 also includes a detection assembly 3 with a lighting device 37 for illuminating the reaction chamber 46 of the reaction carrier 14 , In the embodiment shown, the lighting device 37 designed to illuminate the reaction chamber with a broadband spectrum. For example, the broadband spectrum corresponds to white light. However, adjacent spectral regions as well as infrared spectral regions or ultraviolet spectral regions can also be encompassed by the broadband spectrum.

The detection module 3 further comprises an optical sensor 38 for detecting the optically detectable reaction in the reaction chamber 36 of the reaction carrier 14 , as well as an evaluation unit 4 for the evaluation of the optical sensor recorded data of the optically detectable reaction and determination of a concentration of the component of the gas mixture.

The optical sensor 38 is a multi-channel sensor that can detect multiple color channels. In the embodiment shown, the optical sensor 38 is designed as a digital camera, and will also be digital camera below 38 designated.

The evaluation unit 4 is designed to be used in the evaluation of the data of the optical sensor 38 to weight the color channels.

In 1 is the lighting device 37 for the sake of clarity on the optical sensor 38 opposite side of the reaction carrier 14 arranged. However, the illumination device may be at different positions on the measuring device 12 be arranged and allow appropriate lighting. For example, the illumination and the observation by the optical sensor 38 from the same direction and thus on the same side of the reaction carrier 14 respectively.

The detection module 3 further comprises an evaluation unit 4 , which is designed to determine the concentration of the component to be measured in the gas mixture exclusively from optically determinable parameters of the reaction front. For this purpose, in a detection of a in the reaction chamber 46 spreading reaction front, for example, the front speed and an intensity gradient of the flow in the reaction chamber 46 propagating reaction front measured and determines the concentration of the component to be measured.

However, in the case where the gas mixture does not contain the component to be measured or is below a detection threshold, a functional test of the measuring system must be carried out 10 be performed to rule out a measurement error due to a malfunction of the measuring system, for example due to leakage or clogging of the flow channel.

The 2 and 3 show a more detailed view of the measuring system 10 for measuring or detecting the concentration of gas and / or aerosol-shaped components. Into the measuring device 12 , also referred to as gas measuring arrangement or other gas measuring system, is an exchangeable reaction carrier 14 , also referred to as reaction support unit, manually manually introduced by a user. Here is the measuring system 10 or the measuring device 12 a small, portable device that is mobile and is equipped with a battery as a power supply. 2 shows the measuring device 12 and the reaction carrier 14 separated and 3 shows the measuring device 12 with reaction carrier introduced therein 14 ,

On a housing of the measuring device 12 is the gas conveyor 28 arranged, which is realized by a pump designed as a suction pump. The housing also forms a bearing, in particular slide bearing, for the displaceable reaction carrier 14 , By means of a reaction carrier conveyor 34 with a motor, z. As a trained as a servomotor electric motor and a displaceable by the servo motor in a rotational movement gear, in particular drive roller, the reaction carrier can be moved within the housing of the measuring device, since there is a mechanical contact or a connection between the drive roller and the reaction carrier.

The measuring system 10 includes the measuring device 12 and at least one reaction carrier 14 , The gas inlet channel 16 extends from the gas mixture inflow port 20 to the first gas connection 22 , The gas drainage channel 18 extends from the second gas connection 24 to a gas mixture discharge port 26 ,

The gas inlet channel 16 is made of glass, whereby a chemical reaction or deposition of gas components on the wall of the gas flow channel is prevented or reduced.

A valve 54 is at the gas mixture inlet 20 upstream of the gas feed channel 16 arranged. The valve allows in its first position shown a gas flow through the gas inlet channel 16 and prevents in a second position a gas flow through the gas inlet channel 16 , In the embodiment shown, the valve 54 designed as a 2/2-way valve.

However, it is also possible that the measuring device 12 without a valve 54 at the gas mixture inlet 20 is trained. In this way, the number of components flowed through by the gas mixture before the reaction chamber 46 be reduced and thus prevent or reduce a chemical reaction or deposition of gas components on the components.

Further, in the gas drainage channel 18 a buffer 32 arranged, which a uniform gas flow through the gas outlet channel 18 allows.

The measuring device 12 also includes a reaction support conveyor 34 which involves moving the reaction carrier 14 relative to the gas feed channel 16 and the gas drainage channel 18 allows.

A position sensor 36 serves to detect a relative position of reaction carrier 14 and the gas connections 22 . 24 ,

The optical sensor 38 for detecting an optically detectable reaction is in the form of a digital camera 38 provided and allows a recording of in 1 by the dotted rectangle shown recording field 40 ,

A central control unit 41 is provided, which can process the data detected by the optical sensor and controls the measuring method. In the embodiment shown, the central control unit comprises the evaluation unit 4 ,

The reaction carrier 14 has a plurality of flow channels 42 on, each between two connection elements 44 extend. In the embodiment shown, each of the flow channels forms 42 a reaction chamber 46 , which with reactant 48 is filled. The reactant 48 is a chemical compound which undergoes an optically detectable reaction with a gas to be measured and / or an aerosol-like component of a gas mixture. This is, for example, a colorimetric reaction.

In the embodiment shown, the flow channels are 42 each on its right side with the reagent 48 filled. On the left side of the flow channels 42 another gas treatment element is provided, for example a drying substance.

Every flow channel 42 is a display pen 50 associated with which coding 51 forms, that of the position sensor 36 is detected and an independent positioning of the reaction carrier 14 in each case the flow channels 42 associated relative positions allows. It can also be a different type of coding 51 be provided, for example, an electrical, electronic or magnetic encoding, which of a corresponding position sensor 36 can be detected. Preferably, however, at least in addition is an optical coding 51 provided to a user of the measuring system 10 by looking at the reaction carrier 14 can determine at a glance whether the reaction carrier still unused reaction chambers.

The reaction carrier 14 also has an information field 52 on which information is stored. In the embodiment shown, the information field is 52 formed as an optical information field on which information is stored by the digital camera 38 can be read out. Alternatively, the information field 52 be provided as an electronic memory for information and be designed for example as an RFID chip or SROM chip, which can be read out via wireless or via electrical contacts and / or described.

The recording field of the digital camera 38 is formed in the embodiment shown so that the reaction chambers 46 , the indicator pins 50 , and the information field 52 in each case at least one relative position of the reaction carrier 14 in the measuring device 12 through the digital camera 38 be recorded. That way, the digital camera can 38 on the one hand for the detection of the optically detectable reaction of the reactant 48 in the reaction chambers 46 of the reaction carrier 14 and on the other hand for reading the information in the information field 52 and as a position sensor 36 for detecting the relative position of the reaction carrier and the gas ports 22 . 24 be used. However, it is also possible that position sensor 36 and a read-out device for reading out the information field 52 are formed as one or two separate devices.

A functional test of the measuring system 10 in particular, in the case where the gas mixture does not contain the component to be measured or is present below a detection threshold at which a flow through the flow channel optically via the optical sensor 38 can be measured is described below.

In the 4A and 4B is each an enlarged portion of a flow channel 42 a reaction carrier 14 shown according to a first embodiment. The flow channel 42 is with particles 100 filled. According to the first embodiment, the particles 100 different sizes, wherein in the in 4A shown starting position of the particles 100 the particles 100 mixed in different sizes. 4A shows the section of the flow channel 42 at a time before a gas mixture through the flow channel 42 flows, with the particles 100 each present in a starting position.

4B shows the section of the flow channel 42 at a time at which a gas mixture through the flow channel 42 flows. The gas flow turns the particles 100 acted upon in a flow position. In the in 4B shown first embodiment, the particles 100 with different size at least partially segregated by the gas flow. For example, fine particles are washed out and settle in places with a lower flow velocity. Large particles can change their orientation in the gas stream and perform, for example, a rotary motion. The particles are designed so that the particle 100 in the in 4A shown starting position and the particles 100 in the in 4B shown flow position can be visually distinguished. The above-described changes in position of the particles of different size lead to a changed intensity distribution when taking pictures of the flow channel 42 before the gas flow and during the gas flow.

5 2 shows a diagram of the intensity profiles of all image pixels, a photograph of a flow channel according to the first embodiment, wherein a deviation from a mean value is indicated on the vertical axis and the time is plotted on the horizontal axis, wherein the time at which the gas mixture through the flow channel 42 flows, ie the start of the gas conveyor 28 , indicated by the vertical dashed line. Prior to delivering a gas flow through the flow channel, on the left half of the graph, the intensity profiles show a small deviation from the mean. Once the gas flow through the flow channel 42 the particles are flowing 100 acted upon by the flow in its flow position, wherein the particles 100 different size at least partially segregate. The position change of the particles 100 causes a change in the image, with the segregation of the particles 100 different size causes a contrast enhancement and can be seen in a significantly increased deviation from the mean in the intensity distribution. From the optically detectable change in position of the particles 100 can thus be checked whether a mass flow has taken place through the flow channel. In this way, the function of the gas delivery assembly 2 be checked.

The size distribution of the particles 100 different size is selected so that the largest possible change in the deviation of the intensity distribution in the change in position of the particles 100 is reached. The particles 100 can through the reactant 48 may be formed or may consist of another substance and with the reagent 48 be mixed or in a separate section of the flow channel 42 be arranged. Preferably, the particles comprise 100 different size very fine-grained particles that are immediately washed out in case of a gas flow and a rapid change in position of the particles 100 and a quick detection of the gas flow.

6 shows a section of a flow channel 42 a second embodiment of a reaction carrier 14 , The flow channel 42 includes a first section on the left which contains the reaction chamber 46 with the reagent 48 forms, and a second section 101 on the right, which with particles 102 is filled, wherein the particles have a flow shape. The flow shape of the particles 102 causes the particles in a gas flow in a predetermined orientation in the flow direction to align in a defined flow position. In 6 a gas flow takes place from left to right, as indicated by the arrow, and all particles 102 are aligned in their flow position.

The 7A and 7B each show a detailed view of the second section 101 the second embodiment. In the embodiment shown, the particles have 102 with flow shape a teardrop shape and have a color marking 103 on. However, it is also possible to choose a different flow shape, which is an orientation of the particles 102 in a predetermined orientation in the flow direction causes, for example, a rod shape or disc shape.

The color mark 103 on the one hand, to better distinguish the particles 102 from others from other particles in the flow channel 42 , For example, reactant 48 , be provided. On the other hand, the color marking can be designed so that the color marking is aligned in the flow position so that a better optical distinction between the starting position and flow position of the particles 102 with flow shape is made possible.

7A shows a detailed view of the second section 101 the second embodiment in which the particles 102 are arranged with flow shape in a starting position. In the starting position, the orientation of the various particles is essentially random.

7B shows the detail view of the second section 101 with a flow through the flow channel 42 in the direction of the arrow. The particles 102 are acted upon by the flow in its flow position and rotate in their predetermined orientation in the flow direction. In the embodiment shown results from the regular arrangement of the particles 102 in their flow position against the chaotic random orientation of the particles 102 in the starting position a more homogeneous distribution of color marks 103 compared to the distribution in 7A ,

The color mark 103 or the particle shape is chosen so that the color marks 103 or an area of the particles 102 in relation to a particular direction of observation 105 of the optical sensor 38 are oriented in the flow position to the observation direction, while in the random orientation of the particles 102 in the starting position the color markings 103 or the Surfaces of the particles in the observation direction are only partially visible.

The 8A and 8B show a flow channel 42 a reaction carrier 14 according to a third embodiment. The flow channel 42 is at least partially with particles 104 filled, which have a flow shape analogous to the previous embodiment. In addition, the particles exhibit 104 of the third embodiment has an electrical property to pass through one of the particles 104 acting electrical restoring force to be moved to a reset position, wherein the particles 104 are designed so that the particles in the reset position and the particles 104 can be visually distinguished in the flow position.

In the present embodiment, the electrical property is an electric dipole moment, wherein the particles 104 may have a permanent dipole moment or an induced dipole moment. The electrical restoring force is generated by an external electric field, in which align the electric dipoles. In the embodiment shown, the electric field is through the field lines 106 in 8A shown. The electric field is controlled by a reset device 107 generated. The reset device 107 can in the measuring device 12 or in the reaction carrier 14 be formed, for example, by parallel to the flow channel 42 running capacitor plates.

Due to the transparent flow channel 42 with the particles 104 , the reset device 107 , the optical sensor element 38 for detecting the change in position of the particles and a control unit 108 , which is designed to be detected by means of the detected change in position of the particles 104 determining the flow of a gas or other fluid becomes an optical flow sensor 109 educated. The flow sensor 109 can in addition to the application shown in a measuring system described above 10 also be used to measure the flow of other fluids.

8A shows the particles 104 in their reset position, in which the particles 104 in the electric field 106 are aligned. In this embodiment, it is also possible to move the particles at the beginning of a measurement by the restoring force in its reset position, in which the particles 104 have a defined orientation. In this way, the optical contrast in the change in position of the particles 104 be improved by, for example, color markings 103 or certain areas of the particles 104 in a position to the observation direction 105 point and in the other position from the direction of observation 105 face away.

By the particles 104 can be acted upon by the restoring force in a specific reset position also repeated or continuous measurements can be made. Thus, at the beginning of each measurement by applying an electric field, the particles 104 Align in their reset position and after subsequent shutdown of the electric field, the particles are directed 104 in the present flow in their flow position.

In addition, a sensitivity of the measurement can be adjusted by a low restoring force the particles 104 acted upon in their reset position and thus only at a certain flow the particles 104 be acted upon with sufficient force in the direction of the flow position, so that a change in position occurs to the flow position.

Further, by the the return device 107 a dynamic modulation of the restoring force can be made. The dynamic modulation can for example be made so that the particles 104 between reset position and flow position to move back and forth, for example, with a sinusoidal voltage with adjustable offset, or are held via a control loop on a tipping point, the measurement is largely independent of the mechanical properties of the particles in this way. The required voltage then serves as a measure of the flow velocity.

9 shows an alternative embodiment of an optical flow sensor 109 with a flow channel 42 a fourth embodiment of a reaction carrier 14 , The particles 110 have a flow shape similar to the second and third embodiments and additionally have magnetic properties to be moved by a force acting on the particles magnetic restoring force in a reset position, wherein the particles 110 are designed so that the particles 110 in the reset position and the particles in the flow position can be visually distinguished.

A reset device 107 creates a magnetic field in which the particles 110 align in their reset position, as in 9 shown. The measurement is essentially analogous to the previous embodiment, wherein instead of the electric field, the magnetic field is changed. The particles 110 are for example metallic particles.

It is also possible that particles 100 . 102 . 104 or 110 are provided, which have mechanical properties, by a force acting on the particles mechanical restoring force in a Return position to be moved, wherein the particles are formed so that the particles in the reset position and the particles in the flow position can be optically distinguished. For example, the particles can be embedded in an elastic matrix or even form an elastic matrix. The particles may also have electrical properties, for example by a magnetization or a permanent electric dipole moment, so that the particles interact with one another and a preferred position of the particles is formed, which forms a return position. In this way, the particles are deflected only from a threshold value of the flow strength from the preferred position into the flow position.

In particular, it is also possible to combine the various embodiments described above with one another. For example, the particles 104 be embedded with electric dipole moment in an elastic matrix and thus on the one hand an adjustable electrical restoring force and on the other hand, a constant mechanical restoring force on the particles 104 Act.

As a measure of the flow can be provided on the one hand a determination of a fixed or variable threshold, wherein it is determined that there is a flow above the threshold value of the flow strength. On the other hand, the contrast can be used by the change in position as a measure of the flow rate or a variable restoring force can be used, for example, via the restoring force required for the reset to determine the flow rate.

The following is a measuring method with reference to the 2 and 3 described.

The reaction carrier 14 gets into an insertion opening 80 in a housing 82 the measuring device 12 introduced. The reaction carrier 14 is inserted by hand into the insertion, from the reaction support conveyor 34 recorded and transported forward in the import direction.

When transporting the reaction carrier 14 goes through the information field 52 of the reaction carrier 14 the recording field 40 the digital camera 38 , with the information on the information box 52 from the digital camera 38 be detected and in an evaluation of the central control unit 41 can be evaluated. It is also possible that the reaction carrier is positioned in a read-out position in which a readout of the information field 52 is possible. In the embodiment shown, the information is on the information field 52 optically stored and can thus easily from the digital camera 38 be read out. Alternatively, it is also possible that an electronic information field 52 is provided, which is designed for example as an active or passive RFID chip or SRAM chip and can be read out via radio or via electrical contacts. The electrical contacts are preferably via data lines to the inlet and outlet openings of the flow channels 42 and gas nozzles made of an electrically conductive material, so that a power or data connection between the SRAM chip and a corresponding read-out device is made while the gas nozzles are in the inlet and outlet openings.

In a first process steps are on the information field 52 contained information of the reaction carrier 14 , in particular with respect to the component of the gas mixture to be measured and a corresponding concentration range, read out.

Subsequently, the reaction carrier 14 in a relative position to the gas connections 22 . 24 the measuring device 12 positioned, with a flow channel 42 which is an unused reaction chamber 46 in which in 3 Example shown in the insertion direction first flow channel 42 of the reaction carrier 14 ,

A connection between the gas connections 22 . 24 is through the second flow channel 42 produced.

Before the start of the gas conveyor 28 becomes a reference image of the flow channel 42 taken, whereby the particles 100 . 102 . 104 or 110 are in a starting position. As far as provided, the particles can 104 or 110 be acted upon by the restoring forces in their return positions before the reference image of the flow channel 42 is recorded. In this case, the reset position corresponds to the home position.

After receiving the reference image promotes the gas conveyor 28 a gas mixture to be measured through the drainage channel 18 , the second flow channel 42 and the gas inlet channel 16 where the digital camera 38 a possible optically detectable reaction in the reaction chamber 46 recognizes.

During the conveyance of the gas mixture through the gas conveyor 28 takes the digital camera 38 a flow pattern of the flow channel 42 on. This flow pattern can, for example, both for the optical detection of the flow through the flow channel 42 as well as for the detection of the optically detectable reaction.

The control unit 108 evaluates the reference image and the flow image of the digital camera 38 from and determined by the detected change in position of the particles 100 . 102 . 104 . 110 the flow of the through the flow channel 42 flowing gas stream.

Preferably, the digital camera takes 38 continuously flow images of the flow channel 42 on to a continuous optical. Detection of the flow through the flow channel 42 and to enable the optically detectable reaction.

Preferably, the measuring system generates 10 a restoring force during the conveyance of the gas stream, which acts on the particles in a return position. By adaptation and in particular dynamic modulation of the restoring force, the accuracy of the determination of the flow strength can be increased.

The detection module 3 detects one in the flow direction in the reaction chamber 46 propagating reaction front and its velocity during the feeding of the gas mixture and determines a preliminary measurement of the concentration of the component of the gas mixture to be measured from the speed of the reaction front.

A final measurement result of the concentration of the component of the gas mixture is determined and output after completion of the feeding of the mixed gas.

If the component of the gas mixture to be determined is not contained in the gas mixture or is in a concentration below a detection threshold of the concentration range of the present reaction carrier 14 before, so no optically detectable reaction in the reaction chamber 46 determined, it forms so no reaction front in the reaction chamber 46 out.

A corresponding result of the measurement is displayed by the measuring device, for example optically or acoustically.

Preferably, each time a connection is made between the gas ports 22 . 24 via a flow channel 42 a check of leakage currents instead.

In a first step, the gas connection 24 the gas drainage channel 18 with the associated connection element 44 of the reaction carrier 14 connected. In a second step, gas is passed through the gas drainage channel 18 and the associated flow channel 42 of the reaction carrier 14 promoted, wherein the gas flow is measured through the gas outlet channel for checking leakage currents. If the system of gas drainage channel and flow channel is gas-tight, then essentially no gas flow through the gas drainage channel 18 measured as the flow channel 42 of the reaction carrier 14 over that of the sealing device 62 closed second connection element 44 is sealed gas-tight.

In a further step, the gas flow channel 16 upstream through the valve 54 closed and the gas connection 22 of the gas inlet channel 16 comes with the corresponding connection element 44 of the reaction carrier 14 connected. Subsequently, gas is passed through the gas conveyor 28 through the gas drainage channel 18 , the flow channel 42 and the gas inlet channel 16 promoted, wherein the gas flow through the gas drainage channel to check leakage currents is measured. Is the system of gas drainage channel 18 , Flow channel 42 and gas inlet channel 16 gas-tight, so there is essentially no gas flow through the gas drainage channel 18 measured, since the gas inlet channel 16 through the valve 54 is sealed gas-tight.

In a gas-tight measuring system 10 , in which prior to checking the leakage flows normal pressure in gas drainage channel 18 , Flow channel 42 and / or gas inlet channel 16 is present, the measurement of substantially no gas flow described in the preceding paragraphs is to be understood as meaning that an essentially exponentially decreasing gas flow following the vacuum is measured. In other words, the measured gas flow in a gas-tight measuring system 10 at the beginning of the measurement in the channels 16 . 18 . 42 amount of gas present, which in the review of the leakage flows through the gas conveyor 28 is pumped out.

If the check is a leakage flow, ie a gas flow beyond the gas flow mentioned in the previous paragraph through the gas drainage channel 18 , measured, then a corresponding error message by the measuring device 12 output. The flow channel 42 on the reaction carrier 14 or gas drainage channel 18 and gas inlet channel 16 the measuring device 12 can then be checked by the user, for example.

It is also possible that already in a first step both gas connections 22 . 24 the gas drainage channel 18 and the gas inlet channel 16 with the corresponding connection elements 44 of the flow channel 42 be connected and carried out in accordance with a single check of leakage currents.

LIST OF REFERENCE NUMBERS

2

Gas conveyor assembly

3

detection assembly

4

evaluation unit

10

measuring system

12

measuring device

14

reaction support

16

Gas inlet channel

18

Gas drainage channel

20

Gasgemischeinströmöffnung

22

gas connection

24

gas connection

26

Gasgemischausströmöffnung

28

Gas conveyor

30

Flow Sensor

31

Control / regulation unit

32

buffer

34

Reaction carrier conveyor

36

position sensor

37

lighting device

38

Digital camera / optical sensor

40

receptive field

41

central control unit

42

flow channel

44

connection elements

46

reaction chamber

48

reactant

50

indicator pin

51

encoding

52

information field

54

Valve

76

evaluator

78

memory device

80

insertion

82

Housing (the measuring device)

100

particle

101

section

102

particle

103

color coding

104

particle

105

direction of observation

106

electric field

107

Reset device

108

control unit

109

optical flow sensor

110

particle

Claims (10)

Reaction carrier ( 14 ) for a measuring system ( 10 ) for measuring a concentration of gas and / or aerosol-shaped components of a gas mixture with at least one flow channel ( 42 ), wherein the flow channel ( 42 ) a reaction chamber ( 46 ) with a reactant ( 48 ), which is designed to enter into an optically detectable reaction with at least one component of the gas mixture to be measured or a reaction product of the component to be measured, characterized in that the flow channel ( 42 ) at least partially with particles ( 100 . 102 . 104 . 110 ) is filled, which have a starting position before the gas mixture through the flow channel ( 42 ), and which by a gas flow through the flow channel ( 42 ) are subjected to a flow position, wherein the particles ( 100 . 102 . 104 . 110 ) are formed so that the particles ( 100 . 102 . 104 . 110 ) in the starting position and the particles ( 100 . 102 . 104 . 110 ) can be visually distinguished in the flow position. Reaction carrier according to claim 1, wherein the particles ( 100 ) have different sizes and wherein in the starting position particles ( 100 ) of different sizes are mixed and in the flow position the particles ( 100 ) of different size are at least partially segregated. Reaction carrier according to claim 1 or 2, wherein the particles ( 102 . 104 . 110 ) have a flow shape to align in a flow of gas in a predetermined orientation in the flow direction in its flow position. Reaction carrier according to one of the preceding claims, wherein the particles ( 104 . 110 ) have mechanical, electrical and / or magnetic properties in order to be able to penetrate through one of the particles ( 104 . 110 ) mechanical, electrical and / or magnetic restoring force to be moved to a reset position, wherein the particles ( 104 . 110 ) are formed so that the particles ( 104 . 110 ) in the reset position and the particles ( 104 . 110 ) can be visually distinguished in the flow position. Measuring system ( 10 ) for measuring a concentration of gas- and / or aerosol-shaped components of a gas mixture with a reaction carrier ( 14 ) according to one of the preceding claims and a measuring device ( 12 ), which has an optical sensor ( 38 ), which the flow channel ( 42 ) of the reaction carrier ( 14 ) and is adapted to the initial position and flow position of the particles ( 100 . 102 . 104 . 110 ) optically. Measuring system according to claim 5, wherein the measuring device ( 12 ) and / or the reaction carrier ( 14 ) is adapted to an electric or magnetic field in the flow channel ( 42 ) of the reaction carrier ( 14 ) to create. Measuring method for measuring a concentration of gas- and / or aerosol-shaped components of a gas mixture with a reaction carrier according to one of claims 1 to 4 or a measuring system according to one of claims 5 or 6, with the method steps: Recording a reference image of the flow channel ( 42 ) before a gas flow through the flow channel ( 42 ), whereby the particles ( 100 . 102 . 104 . 110 ) are in their home position; Recording a flow pattern of the flow channel ( 42 ) while conveying a gas flow through the flow channel ( 42 ); and determination of the through the flow channel ( 42 ) flowing gas stream by evaluation of the reference image and the flow pattern. Measuring method according to claim 7, with the method step: generating a restoring force during the conveyance of the gas flow through the flow channel, which particles ( 104 . 110 ) are loaded in a reset position. Measuring method according to claim 8, with the method step: dynamic modulation of the restoring force during the conveyance of the gas flow through the flow channel, so that the particles ( 104 . 110 ) are moved back and forth between the return position and the flow position or held in a position between the return position and the flow position. Optical flow sensor ( 109 ) for determining a flow of a fluid, with a transparent flow channel ( 42 ), which at least partially with particles ( 104 . 110 ), which have a flow shape in order to align themselves in a flow of gas in a predetermined orientation in the flow direction into a flow position and which have mechanical, electrical and / or magnetic properties in order to pass through one of the particles ( 104 . 110 ) acting mechanical, electrical and / or magnetic restoring force to be applied to a reset position, wherein the particles ( 104 . 110 ) are formed so that the particles ( 104 . 110 ) in the reset position and the particles ( 104 . 110 ) can be visually distinguished in the flow position; a reset device ( 107 ) for generating the mechanical, electrical and / or magnetic restoring force; an optical sensor element ( 38 ), which is designed to change the position of the particles ( 104 . 110 ) from the home position to the flow position; and a control unit ( 108 ), which is designed to be detected by means of the detected change in position of the particles ( 104 . 110 ) to determine the flow of the fluid.

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